J. R. Blair-West

Prolonged intracerebroventricular infusion of neurosteroids affects cognitive performances in the mouse.

The effects of prolonged intracerebroventricular (i.c.v.) steroid infusions on memory performances (Y-maze arm discrimination test) and on neurosteroids brain levels were studied in young adult male mice. The Y-maze test consisted of two trials separated by a time interval. In the first trial, one arm of the maze (subsequently called novel arm) was closed, and mice were allowed to visit the two accessible arms. After a short 2-h intertrial interval (ITI), control mice explored preferentially the novel arm, whereas with a longer 6-h ITI, they did not remember the location of the novel arm and performed at random level (33% of time spent in each arm). Using a 2-h ITI, allopregnanolone (THPROG, 0.5 and 1 ng/h) decreased memory performances to random level after 3 and 6 days of infusion. Conversely, with a 6-h ITI, pregnenolone sulfate (PREG S, 10, 50, and 100 ng/h) significantly increased memory performances after 3 days, but only the smallest dose was still effective after 6 days. THPROG infusion (1 ng/h) increased the forebrain concentration of 5alpha-dihydroprogesterone (DHPROG) and tended to increase its own level. PREG S administration (10 ng/h) increased its own concentration and tended to increase those of pregnenolone (PREG) and of further metabolites. In conclusion, the memory-enhancing effects of PREG S and the inhibitory ones of THPROG have been confirmed. A persistent, however moderate, increase of PREG S brain concentration might be of interest for the treatment of amnesic deficits.

Change in Salt Intake Affects Blood Pressure of Chimpanzees. Implications for Human Populations

Background— Addition of up to 15.0 g/d salt to the diet of chimpanzees caused large rises in blood pressure, which reversed when the added salt was removed. Effects of more modest alterations to sodium intakes in chimpanzees, akin to current efforts to lower sodium intakes in the human population, are unknown. Methods and Results— Sodium intakes were altered among 17 chimpanzees in Franceville, Gabon, and 110 chimpanzees in Bastrop, Tex. In Gabon, chimpanzees had a biscuit diet of constant nutrient composition except that the sodium content was changed episodically over 3 years from 75 to 35 to 120 mmol/d. In Bastrop, animals were divided into 2 groups; 1 group continued on the standard diet of 250 mmol/d sodium for 2 years, and sodium intake was halved for the other group. Lower sodium intake was associated with lower systolic, diastolic, and mean arterial blood pressures in Gabon (2-tailed P<0.001, unadjusted and adjusted for age, sex, and baseline weight) and Bastrop (P<0.01, unadjusted; P=0.08 to 0.10, adjusted), with no threshold down to 35 mmol/d sodium. For systolic pressure, estimates were −12.7 mm Hg (95% confidence interval, −16.9 to −8.5, adjusted) per 100 mmol/d lower sodium in Gabon and −10.9 mm Hg (95% confidence interval, −18.9 to −2.9, unadjusted) and −5.7 mm Hg (95% confidence interval, −12.2 to 0.7, adjusted) for sodium intake lower by 122 mmol/d in Bastrop. Baseline systolic pressures higher by 10 mm Hg were associated with larger falls in systolic pressure by 4.3/2.9 mm Hg in Gabon/Bastrop per 100 mmol/d lower sodium. Conclusions— These findings from an essentially single-variable experiment in the species closest to Homo sapiens with high intakes of calcium and potassium support intensified public health efforts to lower sodium intake in the human population.

Neural correlates of the emergence of consciousness of thirst

Thirst was induced by rapid i.v. infusion of hypertonic saline (0.51 M at 13.4 ml/min). Ten humans were neuroimaged by positron-emission tomography (PET) and four by functional MRI (fMRI). PET images were made 25 min after beginning infusion, when the sensation of thirst began to enter the stream of consciousness. The fMRI images were made when the maximum rate of increase of thirst occurred. The PET results showed regional cerebral blood flow changes similar to those delineated when thirst was maximal. These loci involved the phylogenetically ancient areas of the brain. fMRI showed activation in the anterior wall of the third ventricle, an area that is key in the genesis of thirst but is not an area revealed by PET imaging. Thus, this region plays as major a role in thirst for humans as for animals. Strong activations in the brain with fMRI included the anterior cingulate, parahippocampal gyrus, inferior and middle frontal gyri, insula, and cerebellum. When the subjects drank water to satiation, thirst declined immediately to baseline. A precipitate decline in intensity of activation signal occurred in the anterior cingulate area (Brodmann area 32) putatively related to consciousness of thirst. The intensity of activation in the anterior wall of the third ventricle was essentially unchanged, which is consistent with the fact that a significant time (15–20 min) would be needed before plasma Na concentration changed as a result of water absorption from the gut.

Thirst induced by increasing brain sodium concentration is mediated by brain angiotensin

Thirst, the longing or compelling desire to drink, arises physiologically by two main mechanisms-extracellular and cellular dehydration. The hormone angiotensin II has been implicated in the former but not in the latter brain mechanism. To test this apparent difference, experiments in 5 mammalian species examined the effect of intracerebroventricular infusion of losartan, an angiotensin II type I receptor antagonist, on the third induced by intracerebroventricular infusion of an artificial cerebrospinal fluid made hypertonic by the inclusion of 500 mM NaCl. The losartan infusion reduced the water intake due to increased brain sodium concentration in all 5 species, cattle, sheep, rabbits, rats and mice. Thus, the thirst evoked by cellular dehydration, as well as the thirst evoked by extracellular dehydration, may be mediated by angiotensin II.

THE EFFECT OF ALDOSTERONE, CORTISOL, AND CORTICOSTERONE UPON THE SODIUM AND POTASSIUM CONTENT OF SHEEP'S PAROTID SALIVA*

Sodium depletion in the sheep results in a fall in parotid salivary sodium/potassium concentration ratio (Na/K) from a normal 25 to 40 (Na, 170 to 185 and K, 4 to 6 mEqper L) to as low 0.3 (Na, 40 and K, 133 mEqper L) (1, 2). Earlier work in this laboratory suggested that this reciprocal alteration in the concentration of salivary sodium and potassium was due predominantly to the simultaneous operation of 1) a fall in the salivary secretion rate and 2) an increase in the secretion of electrolyte-active adrenal steroids. If suitable allowance were made for the effects of variation in the parotid salivary secretion rate and the latency of the response, it was proposed that the salivary Na/K ratio could be used as an index of the release of electrolyte-active steroid into the circulation (2-5). Cortisol (6), corticosterone (6), and aldosterone (7-9) have been identified in sheep adrenal venous blood. In order to obtain a basis for evaluating the contribution of each of these components of the adrenal secretion to the fall in parotid salivary Na/K ratio observed during different physiological states, the effects of these steroids upon salivary Na and K were studied in a series of experiments in normal and adrenalectomized sheep.

Effect of aging on regional cerebral blood flow responses associated with osmotic thirst and its satiation by water drinking: a PET study

Levels of thirst and ad libitum drinking decrease with advancing age, making older people vulnerable to dehydration. This study investigated age-related changes in brain responses to thirst and drinking in healthy men. Thirst was induced with hypertonic infusions (3.1 ml/kg 0.51M NaCl) in young (Y) and older (O) subjects. Regional cerebral blood flow (rCBF) was measured with positron emission tomography (PET). Thirst activations were identified by correlating rCBF with thirst ratings. Average rCBF was measured from regions of interest (ROI) corresponding to activation clusters in each group. The effects of drinking were examined by correlating volume of water drunk with changes in ROI rCBF from maximum thirst to postdrinking. There were increases in blood osmolality (Y, 2.8 ± 1.8%; O, 2.2 ± 1.4%) and thirst ratings (Y, 3.1 ± 2.1; O, 3.7 ± 2.8) from baseline to the end of the hypertonic infusion. Older subjects drank less water (1.9 ± 1.6 ml/kg) than younger subjects (3.9 ± 1.9 ml/kg). Thirst-related activation was evident in S1/M1, prefrontal cortex, anterior midcingulate cortex (aMCC), premotor cortex, and superior temporal gyrus in both groups. Postdrinking changes of rCBF in the aMCC correlated with drinking volumes in both groups. There was a greater reduction in aMCC rCBF relative to water drunk in the older group. Aging is associated with changes in satiation that militate against adequate hydration in response to hyperosmolarity, although it is unclear whether these alterations are due to changes in primary afferent inflow or higher cortical functioning.

The role of angiotensin II in ingestive behaviour: A brief review of angiotensin II, thirst and Na appetite

From the outset, the study of angiotensin II (Ang II) in body fluid homeostasis has been both complicated and intriguing. Since the publication of an early report of the dipsogenic action of this peptide, the pursuit of the role of Ang II in thirst and Na appetite has continued for the last 25 years. This pursuit captured the attention of all workers interested in the behavioural/physiological regulation of body fluid balance, with major contributions being made by James T. Fitzsimons and his colleagues. In spite of its powerful dipsogenic actions, delineation of its precise role in physiological thirst has been elusive and difficult to demonstrate. The influence of Ang II on Na intake took longer to show convincingly. However, in contrast to thirst, the role of Ang II in physiological Na appetite has been demonstrated clearly. The technological advances made during the recent years have greatly increased our ability to delineate the neurobiological context of Ang II-mediated responses. Thus, the future is promising in regard to illuminating the subtleties of the role of Ang II in body fluid balance.

Role of Brain Angiotensin in Thirst and Sodium Appetite of Rats

The role of brain angiotensin II (ANG II) in water, Na and food intake of rats was studied. Intracerebroventricular (i.c.v.) infusion (100 micrograms/h) of the non-peptide ANG II receptor antagonist losartan (type 1), but not PD123319 (type 2), completely blocked water intake caused by i.c.v. infusion of ANG II at 50 ng/h. Following food deprivation, food intake was reduced by PD123319 and associated water intake was decreased by losartan or PD123319. Neither water intake after water deprivation nor Na intake after Na depletion was altered by losartan or PD123319. In conclusion, evidence was consistent with a role for brain ANG II in both food and water intake after food deprivation but not in thirst subsequent to water deprivation or Na intake after Na depletion alone.

Effect of Variations of Plasma Sodium Concentration on the Adrenal Response to Angiotensin II

The secretion rate of aldosterone was increased by infusion of valine-5-angiotensin II into the adrenal arterial blood supply of sheep. The dimensions of the increase in aldosterone output were inversely related to the control plasma concentration. This high aldosterone secretion was reduced substantially by concurrent adrenal infusion of concentrated NaCl solution which increased plasma sodium concentration by approximately 10 meq/liter. The reduction of aldosterone secretion occurred within 20 minutes. Angiotensin II infusion did not increase the secretion rates of cortisol or corticosterone. The significance of the finding that environmental sodium concentration has different effects on the aldosterone-stimulating action and the pressor action of angiotensin II is discussed.

Evidence that brain angiotensin II is involved in both thirst and sodium appetite in baboons

The roles of ANG II in the brain mechanisms subserving thirst and Na appetite in baboons were investigated by chronic intracerebroventricular infusions of ANG II and AT1-receptor antagonists using subcutaneous miniosmotic pumps and by oral administration of captopril. ANG II at 3 or 5 micrograms/h for 7 days increased water intake from 2,455 +/- 107 to 7,052 +/- 562 ml/day by day 6 and 300 mM NaCl intake from 8.3 +/- 1.1 to 275 +/- 87 mmol/day by day 5. Concurrent intracerebroventricular losartan (300 micrograms/h) did not substantially reduce these responses, but they were abolished by intracerebroventricular ZD-7155 (50 micrograms/h). The increase of 300 mM NaCl intake when it was offered after intramuscular injection of furosemide, 2 mg . kg-1 . day-1 for 3 days, was unaltered by intracerebroventricular losartan (300 micrograms/h) but was reduced by intracerebroventricular ZD-7155 (50 micrograms/h) infused throughout Na depletion/repletion; oral captopril (1 g, 3 and 18 h before access to 300 mM NaCl) also reduced NaCl intake. Restriction of water intake to 25% of daily intake for 3 days caused a high intake of water on day 4, and this was reduced by intracerebroventricular losartan (300 micrograms/h) infused throughout the period of water restriction/rehydration. These novel results in a primate species suggest that brain ANG II is involved in both thirst and Na appetite, acting via AT1 receptors.